Part 1 A boat is pulled by the two forces in the figure, where F =...

The figure below shows the horizontal forces acting on a sailboat moving north at constant velocity,...

The figure below shows the horizontal forces acting on a sailboat moving north at constant velocity, seen from a point straight above its mast. At the particular speed of the sailboat, the water exerts a F with arrow = 400-N drag force on its hull and θ = 35.0°. For each of the situations (a) and (b) described below, write two component equations representing Newton's second law. Then solve the equations for P (the force exerted by the wind on...

The two forces F⃗ 1 and F⃗ 2 shown in the figure (Figure 1) (looking down)...

The two forces F⃗ 1 and F⃗ 2 shown in the figure (Figure 1) (looking down) act on a 16.0-kg object on a frictionless tabletop. Part A If F1=14.0 N and F2=21.0 N , find the magnitude of the net force on the object for (a). F =   N   SubmitRequest Answer Part B Find the direction of the net force on the object for (a). θ =   ∘ from the +x axis SubmitRequest Answer Part C Find the magnitude of...

#1. A water skier is pulled by a boat traveling with a constant velocity. Which one...

#1. A water skier is pulled by a boat traveling with a constant velocity. Which one of the following statements is false concerning this situation? A) The water skier is in equilibrium. ; B) The net acceleration of the skier is zero [m/s]. ; C) The net force on the skier is zero [N]. ; D) There is a net horizontal force on the skier in the direction the boat’s velocity. ; E) The net vertical force on the skier...

A 1,100–N uniform boom at ϕ = 65.5° to the horizontal is supported by a cable...

A 1,100–N uniform boom at ϕ = 65.5° to the horizontal is supported by a cable at an angle θ = 24.5° to the horizontal as shown in the figure below. The boom is pivoted at the bottom, and an object of weight w = 2,150 N hangs from its top. (a) Find the tension in the support cable. (b) Find the horizontal & vertical components of the reaction force exerted by the pivot on the boom. (Assume the positive...

Forces with magnitudes of 800 pounds and 400 pounds act on a machine part at angles...

Forces with magnitudes of 800 pounds and 400 pounds act on a machine part at angles 30° and −45°, respectively, with the x-axis (see figure). Find the direction and magnitude of the resultant force F. (Round your answers to two decimal places.) θ = ° referenced to the horizontal positive x-axis ||F|| = lb

A block with mass 6.00 kg slides on a horizontal floor as it is pulled with...

A block with mass 6.00 kg slides on a horizontal floor as it is pulled with a string by a force of 50.0 N at an angle of 30.0° with the horizontal. The force of friction between the floor and the block is 10 N. A. Draw below a free body diagram for the block. Label all the forces and describe each force: name and source of the force. B. Find the y-component of the net force. Explain your answer....

A 1,300–N uniform boom at ϕ = 60.0° to the horizontal is supported by a cable...

A 1,300–N uniform boom at ϕ = 60.0° to the horizontal is supported by a cable at an angle θ = 30.0° to the horizontal as shown in the figure below. The boom is pivoted at the bottom, and an object of weight w = 1,950 N hangs from its top. A boom of length l with its bottom end on a pivot is shown. The boom points up and to the right and makes an angle ϕ with the...

The helicopter view in the figure below shows two people pulling on a stubborn mule. (Take...

The helicopter view in the figure below shows two people pulling on a stubborn mule. (Take F1 = 145 N and F2 = 75.0 N. ) An illustration shows the helicopter view of a mule being pulled along a forked road in two directions by two men. An x y coordinate system is overlaid on the image, with the origin at the mule's nose, and the mule facing in the positive y-direction. The man on the right is pulling the...

Two forces, vector F 1 = (−4.20î − 3.65ĵ) N and vector F 2 = (−2.30î...

Two forces, vector F 1 = (−4.20î − 3.65ĵ) N and vector F 2 = (−2.30î − 7.60ĵ) N, act on a particle of mass 1.90 kg that is initially at rest at coordinates (+1.75 m, −3.95 m). (a) What are the components of the particle's velocity at t = 11.3 s? (b) In what direction is the particle moving at t = 11.3 s? ° counterclockwise from the +x-axis (c) What displacement does the particle undergo during the first...

Learning Goal: To use the principle of linear impulse to determine the change in velocity of...

Learning Goal: To use the principle of linear impulse to determine the change in velocity of a box subject to multiple forces. The block shown in (Figure 1) has mass m = 48 kg and is subjected to forces F1 = 300 N at an angle θ = 40 ∘ below the horizontal and F2 = 60 N . The coefficient of kinetic friction between the box and the surface is μk = 0.15. What is the velocity of the...